US2285840A

US2285840A - Well survey method and apparatus

Info

Publication number: US2285840A
Application number: US288456A
Authority: US
Inventors: Scherbatskoy Serge Alexander
Original assignee: Well Surveys Inc
Current assignee: Well Surveys Inc
Priority date: 1939-08-04
Filing date: 1939-08-04
Publication date: 1942-06-09
Anticipated expiration: 1959-06-09

Description

June 9, 1942..

s. A. SHERBATSKOY WELL SURVEY METHOD AND APPARATUS Filed Aug. 4. 1959 2 Sheets-Sheet 1 S. A. SCHERBATSKOY WELL SURVEY METHOD AND APPARATUS June 9, 1942.

Filed Aug. 4, 1939 2 sheets-sheet 2 www Patented June 9, 1942 WELLl SURVEY METHOD AND APPARATUS Serge Alexander Scherbatskoy, Tulsa, Okla., as-

signor to Well Surveys, Incorporated, Tulsa, Okla., a corporation of Delaware Application August 4, 1939, Serial No. 288,456

21 Claims.

.Ihis invention relates to a method and device for geophysical exploration and particularly to a device adapted to be lowered into a drill hole and to gather information about the nature of the geological formations adjacent thereto.

Many methods of geophysical exploration are already known and among them several methods of determining the nature of geological formations adjacent drill holes or other openings already present in the area to be studied. Of these methods of well surveying or drill hole prospecting, that of lowering a detector of radiations In order to-avoid this` Source of dimculty and -provide a system that will measure acurately y the self-emitted or reflected radiations from the from radio active material into a drill hole and correlating the measurements made therewith with'the depth at which the measurements are made offers particularly interesting possibilities in that the radiations from radio-active material will penetrate for quite some distance through the surrounding strata and be received by the detector of radiations even though the drill hole may be surrounded by a steel casing and the detector itself securely enclosed in a steel compartment. Furthermore, it has been discovered that there are sufficient differences in the radio activities of the various materials that are likely to surround the drill hole so that practical indications of the various types of material and the interfaces between them may be obtained by this method.

f For the above reasons considerable attention I is now being given to this general process of subsurface geophysical prospecting. However, there is a difilculty involvedin this type of prospecting whichl at times tends to make the results `more confusing than helpful and in any event makes more diicult and less certain the interpretation of the results obtained therein. This d ifliculty is due to the fact that quite often the drilling mud or the oil or the metallic pipe that forms the drill casing, or othermaterials introduced into the area being studied are naturally or become for one reason or another, a source of radiations. When this happens, the radiations received by the detector are no longer a true representation of the normal surrounding strata but are a composite of the` radiations from the normal surrounding strata and the radiations from the introduced source. The same diiculty occurs in measuring reflected radiations, when a source of radiations is lowered into a well and those radiations which pass out into the surrounding strata and are reiiected back are measured as disclosed in appli` cation Serial No. 239,781 filed by Robert E. Fearon on November l0, 1,938, and Patent No. 2,133,776 granted to Bender on October 18', 1938.

normal surrounding strata to the exclusion of these from accidently introduced sources of ra- According to this invention it has been dis.

covered that radiations detected by the ordinary detector of radiations such as an ionization chamber, are of two kinds which may be generally classified as hard and sof While the ratio of soft to h ard radiations at the source is usually fairly constant, the soft radiations have relatively little penetrating power and hence have almost no eifect on the instrument unless they come from closely adjacent formations, those originating further away all being filtered out by the intervening material. The hard radiations on the other hand have a muchgreater penetrating power and are effective not only from close to the detector but from a considerable distance away as well.

Taking advantage of this situation this inventor has found that by measuring both the soft and the hard radiations and then by subtracting this measurement from a measurement, on a sufliciently enlarged scale, of the hard radiations only, he may obtain a measurement or indication of the amount of radiations originating at a point or area removed a definite distance from the detector or that have traveled a denite distance before being reflected to the detector, to the almost entire exclusion of any measurement of radiations originating'immediately adjacent to the detector.

The exact manner in which the present invention is carried into practice and many of its details and vadvantages may be more completely understood by reference to the accompanying drawings and the following detailed descriptions thereof In the drawings: y

Figure 1 is a graphical representation of the effectiveness of the two general types of radiations which originate at various distances from the detector, and also a graphical representation of the manner4 in which they are combined to comple'te well surveying instrument constructed according to the principles of this invention.

In Figure l thel curve H indicates the effect on. the detector of a unit quantity of hard radiation originating at various distances 'from the detector. It will be noted that theieffectiveness ofthe radiation diminishes as the distance from the detector increases.

The curve H+S is a similar graphical illustration of the eiectiveness of the same unit quantity of hard radiation plus the quantity of soft radiation that will usually be encountered therewith. The curves H and H+S are identical for relatively large distances from the detectors for the soft radiations are 'entirely ineffective, but for shorter distances the soft radiations are eiective and hence the curve H+S is above the curve H.

In combining the values indicated by the curves H and H-l-S to get the desired results, the enact of the hard radiations alone is first increased relative to the effect of the hard and soft radiations, by amplification or increase in the sensitivity of the detector or taking the voltage representing the effect across a greater resistance or other means. The curve H is thus caused to become the curve H' the values indicated by which, are great enough so that the values indicated by the H-l-S may be subtracted therefrom. 'I'his may be donel electrically or mechanically in any one of a large number of ways, some of which will be illustrated later, and the result is the values shown by the curve v lying farther away. This is a particular advantage because it is natural .that the articially or accidently introduced sources of radioactivity will lie in the drill hole or immediately surrounding it whereas the formations somewhat further away willl still remain in their normal state. Thus the present invention permits the measurement of the original radioactivity of the formations substantially without interference from anything that may' have been artificially introto the electrodes of the ionization chambers through one or more resistors across which potentials are developed proportional to the current flows through the ionization chambers. arranging the circuit so that the potentials developed are in opposition and on the proper relative scales and measuring the resultant potential.

Specific apparatus capable of use according to the new method is illustrated in Figures 2 and 3 of the drawings in diagrammatic form.

In Figure 2 there is provided a pair of ioniza- 7s v tion chambers I8 and II, each consisting of a pair oi electrodes enclosed in a sealed compartment which contains nitrogen under around 300 pounds ot pressure. In each case the inner electrode I2 is an iron rod about a half an inch in diameter and about flve inches long. The outer electrode I8 is a sheet iron cylinder, open at thev end. about 2 inches in diameter and about 5 inches long. The enclosing. compartment I4 of the ionization chamber I8 is of fairly heavy sheet vsteel preferably approximately three-eighths of an inch in thickness. The enclosing compartment Il of ionization chamber II is of much thinner steel, preferably about one-sixteenth of an inch thick. The thicker .case tends to shield the elements within it from soft radiations whereas the thinner case I5 is unable to do so and the elements within it are subjected both to the hard and to the soft radiations.

According to Figure 2 a potential is applied between the elements of each of the ionization chambers by means of a battery I8, one terminal of which is connected to the central electrodes of both chambers and the other terminal of which is connected through resistors I'I and I8, respectively, to the outer electrodes I8 of the chambers I4 and II. Electrical connections I8 and 20 taken from the opposite ends of resistors I1 and I8 obviously carry va potential equal to the difference between the voltage drop across resistor Il and the voltage drop across resistor I8. This voltage may be conveyed to the surface and recorded.

As was stated above it is not usually desirable to subtract a determination made by one of the ionization chambers from the determination made by thel other ionization chamber when the two are on the same scale of magnitude. In other words, it is more often desirable -to multiply one of the determinations by some constant factor so that the voltages produced across the resistors I1 and I8 will have the approximate relation to each other that is indicated by the curves H' and H-i-S Figure 1. In the present device this may be expeditiously accomplished by properly choosing the resistors I1 and I8. For example, if the resistor I8 is higher than the resistor I1 the potential drop across it for a given current flow will be greater than would the potential drop across resistor I1 for the same current flow. Thus the resistors may be chosen so as to cause the potentials developed to bear the proper relation to each other. For example, it has been found that a resistance of 1I)12 ohms for resistor I1 and 2X 1911 for resistor I8 will give approximately the proper balance between the voltages developed in the two resistors.

As an alternative arrangement that shown by Figure 3 may be used. In the device here shown the ionization chambers are similarly constructed but diiferently connected. Instead of connecting both of the central electrodes I2 to one terminal of a battery, the two electrodes are ccnnected to the opposite terminal of a battery ZI. From an intermediate terminal of the battery the outer electrodes I3 are connected through a resistor 22 to an intermediate terminal of the battery.

Connections

23 and 24 to opposite ends oi' resistor 22 receive a potential which represents the difference between the potentials appliedto resistor 22 by the currents flowing in the two vionization chambers.

With this arrangement it is necessary to adjust the intermediate connection to the battery so as to apply the proper amount of potential to each of the two ionization chambers so that the cur- -the intensity o1 the radiations, both of the hard rent passing through them will be in the proper relation to be directly subtracted for there is but a single resistor and hence nok separate adjustrnent ci resistance for each of the ionization chambers is possible. Furthermore, lthis moditien has a slight disadvantage in that the operation ci one ionization chamber has a slight 'effect on the operation of the other by changing the potential across resistor' 22 and hence the potential on the other ionization chamber. Still further the battery must be of approximately twice the voltage necessary according to Figure 2 and differences between the two halves of the battery can conceivably unbalance the system. These diiliculties are not so lserious however but what the device can be used with quite satisfactory results even in thisforrn.

As shown in Figure 4 the detecting arrangement of Figure 2, exactly as there shown,-is encased in a cylindrical housing that is arranged to be hermetically sealed so as to protectthe enclosed instruments from oil or water or other materials that may be encountered. in a well. The housing 25 also encloses an amplifier 26 which receives the output current from the measuring instrument of Figure 2 and after amplifying this output passes it into a supporting cable 21 which serves to support the casing inthe well and also to convey the indicating current from the amplier to the surface recording apparatus. At the surface the supporting cable 21 passes over a measuring wheel 28 and is wound onto a cable reel 29 which Vis driven by a source of power not shown vto raise and lower the housing in the well during the progress of the surveying operation.

From the cable reel 29 the indicating currents are taken through slip rings 30 and brushes 3| and carried to an amplifier 32 from which they pass to a recorder 33 which records them on a recording strip 34 which is driven by a mechanical connection .35 from the-measuring wheel 28 so that the tape will move in accordance with the movements of the housing in the well and will thus correlate the measurements of radioactivity with indications of the position of the capsule in the well. This mechanical connection 35 may be replaced by an electrical transmission system such as the well known Selsyn transmission 'system if ldesired and this replacement will often be found desirable in field operations because it will permit the recording equipment to be located at some distance from the top1 of the well.

Still other embodiments of the principles of this invention and numerous circuit modications may be made all within the scope ofthe invention. It is therefore to be understood that thel particular embodiments illustrated are but examples of the preferred forms of apparatus to be used according to this invention and that it is not intended that the invention should be limited to these particular forms of apparatus.

I claim:

l. A method of geophysical exploration utilizing radiations of the type that emanate from radioactive materials that comprises measuring the intensity of theradiations, both of the hard and soft variety, present at various locations adjacent the formations to be explored, measuring the intensity of the hard radiations only at the same locations, and combining said two measurements at each location to obtain a differential measurement for each location.

2. A method of geophysical exploration utilizing radiations of the type that emanate from radioactive materials that comprises measuring and soft variety, present at various locations acl- -l jacent the formations to be explored, measuring i the intensity'of the hard radiations only at the same locations, and combining said two measurements at each location -to obtain a comparative measurement for each location, whilebalancing the means for obtaining said original measurements so that radiations from a substantial distance away from the measuring locations have a greater eifect on the diierential measurements than radiations originating closer to said measuring locations.

` 3. A method of geophysical exploration utilizing radiations of the type that emanate from radioactive. materials that comprises measuring at various depths in an opening in the earth the intensity of the radiations, both of the hard and soft variety, present at said depths, measuring the intensity of the vhard radiations only at the same depths, and combining the two measurements at each depth to obtain a differential measurementfor each depth.

4. A method of geophysical exploration utilizlng radiations of the type that emanate-from radioactive materials that comprises measuring at.

various depths in an opening in the earth the intensity of the radiations, both of the hard andl soft variety, present at said depths, measuring the intensity of the hard radiations only at the same depths, and combining the two measurements at each depth. to obtain a differential measurement for each depth, while balancingl` the means for obtaining said original measurements so that radiations from a substantial distance away from the measuring location have a greater eiect upon the differential measurements than radiations originating closer to said measuring locations'.

5. A method of geophysical exploration utilizing radiations of the type that emanate from radioactive materials that comprises continuously measuring throughout a range of depths in an opening in the earth, the intensity of the radiations, both of the hard and soft variety, present at the said depths measuring the intensity of the hard radiations only, at the 'same depths, combining said two series of measurements toobtain a differential measurement for each location and correlating these diierential measurements with measurements of the depths at which they ,arey taken.

6. A device for determining the nature of geological structures that comprises a pair of ionization chambers one of which is shielded against radiations to a greater extent than the other, means for impressing an electrical potential between the electrodes of said ionization chambers. means for measuring the current ilow in the ionization chambers, means for differentially combining said measurements and means for correlating the resulting measurements with indica- A tions of the location of the ionization chambers.

7. A device for determining the nature of geological structures that comprises a pair of ionizavoltage drop developed across said two resistors.

8. A device for determining the nature of geological structures that comprises a pair of ionization chambers one of which is shielded against radiations to a greater extent than the other, a

source of electrical potential connected to both of said ionization chambers, a resistor in series with said source of potential and one of said ionization chambers, a second resistor in series with said source of potential and the other ionization chamber, means to determine the difference between the potentials developed across said resistors, means to determine the position of said,

ionization chambers and means to record the psitions of said ionization chambers in correlation with the difference between the potentials. p

9. A device for determining the nature of geological structures that comprises a pair of ionization chambers one of which is shielded against radiations to a greater extent than the other,'a source of electrical potential one terminal of which is connected to an electrode of each of theionization chambers and the other terminal of which is connected through a resistance to the other electrode of one of the ionization chambers and through a second resistance to the other electrode of the second ionization chamber, means to measure the potential difference be- 'tween the ends of the resistors opposite to those source of electricalpotential connected to the other end of said resistance and to the other electrode of one of said ionization chambers, a

'second source of potential the terminal of which having opposite polarity is attached to the same end of the resistor to. which the first mentioned source of potential is attached and the other terminal of which is attached to the remaining electrode of the other ionization chamber and means for determining and recording the potential drop across said resistance in correlation with an indication o f the position of the ionization chambers.

1l. A device for determining the nature of geological structures adjacent a drill hole or similar opening in the earth which comprises a pair of ionization chambers one of which is shielded against radiations'to a greater extent than the other and both of which are adapted to be lowered into the opening to be explored as a single unit, means for impressing an electrical potential between the electrodes of said ionization chambers, means for measuring the current flow in the ionization chambers, means for diierentially away therefrom, and combining the measurements obtained. 1

14. A method'f geophysical exploration which comprises the steps of measuring at various combining said measurements and means for` n correlating the resulting measurements with indications of the locations of said ionization chambers in the drill hole.

12. A method of geophysical exploration which comprises the-steps of measuring at determinable places a band of radiations emanating from formations adjacent said places, measuring at the same places another band of radiations emanating from said formations adjacent said places, and combining the measurements obtained.

13. A method of geophysical exploration which depths in a bore hole of characteristic of formations closely adjacent thereto, measuring at various depths in said bore hole a characteristic of formations both closely adjacent and farther away therefrom, measuring the depths at which said measurements were obtained, correlating the measurements obtained, and combining the measurements resulting from said correlation with the depth measurements.

15. A method of geophysical exploration which comprises the steps of measuring at various depths in a bore hole a` characteristic of formations adjacent said bore hole, measuring at various depths in the bore hole a diiferent characteristic of formations adjacent said bore hole, combining the measurements of the characteristics within the bore hole, transmitting the combined measurements to the surface. and combining said measurements with the measurements of the depths at which said characteristics were meas- 16. A method of geophysical prospecting which comprises measuring the intensity of radiations of one range of frequencies coming from a forma-` tion about which information is desired, measuring the intensity of radiations of another range of frequencies coming from said formation and combining the measurements obtained.

17. A method of geophysical prospecting that comprises separately measuring the intensity of radiations of a plurality of frequency ranges coming from a formation about which information is desired, and combining the measurements obtained 1s. device zer determining the nature er gee-y logical structures that comprises a pair of ionization chambersvone of which is shielded against radiations to a greater extent than the other,

means for impressing an electrical potential be-l tween the electrodes of said ionization chambers, means foil measuring a function of the current in the ionization chambers, means for differentially combining said measurements and means for cor.

relating the resulting measurements with indications of the location of the ionization chambers.

19. AA device for determining the nature of geological structures that comprises a pair of ionization chambers one of which is shielded against radiations to a greater extent than the other, a source of electrical potential connected to both of said ionization chambers, a resistor in series with said source of potential and one of said ion,- ization chambers, a second resistor in series with saidsource of potential and the other ionization chamber, means to combine the voltages developed 'across said two resistors to produce a signal indicative of a function of said voltages,'and means for indicating said signal.

20. A device for determining the nature of geological structures that comprises a pair of ionization chambers one of which is shielded against radiations to a greater extent than the other, a source of electrical potential connected to both of said ionization chambers, a resistor in series with lsaid source of potential and one of said ionization chambers, a second resistor in series with prises a first and a second independent means for detecting gamma. rays, means for independently translating indications from both of the detect ing means into 'electrical currents, means for combining the currents to produce a single signal indicative of a functional relationship between the combined currents, and means for recording the signal so obtained.

SERGE ALEXANDER SCHERBATSKOY.